[Problem] To provide a bending device with a novel structure capable of efficiently bending a metallic plate without scratching or denting the plate.
[Solution] A device (10) for bending a metallic plate (W) mounted on a pair of movable plates (35, 35) by applying pressing force to the metallic plate by an upper die (20) along a central axis (X), wherein against the biasing force of a coil spring (45), the movable plates move with the extension of the metallic plate during bending, and therefore the metallic plate is not scratched. The upper surface of each of the movable plates is a perfect flat surface, and therefore does not dent the metallic plate being subjected to the pressing force by the upper die. When the pressing force and the load of the metallic plate are removed after the completion of bending, swing members return to the original position thereof, and the movable plates are also returned to the original position thereof by the biasing force of the coil spring, with top parts (42) of fastening members (41) coupling the movable plates to fixed plates (38) functioning as a stopper and holding the movable plates at the original position.
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1. A metal plate bending device comprising a lower die having a main body with a pair of semi-circular cross-sectional recesses formed on an upper surface thereof in a symmetric design with respect to a center line and a pair of swingable members swingably received in said recesses respectively, and an upper die arranged above said lower die movably along the center line, wherein said upper die is moved toward a metal plate mounted on said lower die to impart a press-push force to the metal plate to thereby cause the swingable members to swing and at the same time bend the metal plate along the center line,
wherein each of said swingable member has a movable plate unfixedly and detachably mounted on a completely flat upper surface of said swingable member, and a spring means for providing a biasing force directly to said movable plate to return said movable plate to a standby condition when the press-push force by said upper die is released,
said movable plate providing a completely flat lower surface for slidable, planar contact with the upper surface of said swingable member and providing a completely flat metal plate supporting surface, said movable plate being slidable with respect to said swingable member, and being movable together with said metal plate along with deformation of said metal plate,
wherein a plurality of the metal bending devices are connected in series in a lengthwise direction for bending a metal plate longer than a length of a single metal plate bending device, with a selected one of said movable plates equal to or longer than the length of said long-length metal plate, which is mounted successively over said plural metal plate bending devices.
2. The metal plate bending device according to
3. The metal plate bending device according to
4. The metal plate bending device according to
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The present invention relates to a device used for bending metal plate such as steel, and particularly to a device of a type comprising a lower die having a pair of swingable members of substantially semi-circular cross-section and a vertically movable upper die imparting a press-push force to a metal plate placed on said swingable members at a center position between said swingable members, wherein said lower and upper dies cooperate with each other to bend said metal plate at said center position.
The metal plate bending device of the above-described type is known in, for example, the following Patent Documents 1-3. A metal plate to be bent is placed on the upper plates of a pair of swingable members (or plate supporting members secured thereon, the same shall apply hereinafter) at a starting position wherein the upper plates of the swingable members become flush with each other (which is a position shown in FIG. 1 of Patent Document 1, FIG. 2 of Patent Document 2 and FIG. 3 of Patent Document 3). When an upper die is moved downward to push a center position between the swingable members, the swingable members are rotated in opposite directions so that the metallic plate is bent at the center position. When compared with the device of a time-honored type using a stationary lower die (such as shown in FIG. 3 and FIG. 4 of Patent Document 1), this will provide advantages such as improved machining accuracy.
However, as the metal plate is being bent from its original flat form, its outer surface side will expand due to its material plastic deformation, resulting in out-of-position with respect to the swingable members on which the metal plate is mounted. This will cause formation of scratches on the outer surface of the metal plate and lower its commercial value.
Patent Document 4 proposes, as a solution to this problem, to use a plate supporting member slidably mounted on each of the substantially semi-circular cross-sectional swingable members. More specifically, the plate supporting member 21 is mounted onto the upper surface of the swingable member 15 in such a manner that each upper surface (the metal plate supporting surface) of the swingable member 15 is processed to form a slot 23, and a fastener 25 passing through the slot 23 is screwed to the swingable member 15, thereby allowing the plate supporting member 21 to slide and move in in-and-out directions with respect to the upper surface of the swingable member 15. In such a mounting manner, when the metal plate W supported on the plate supporting members is elongated due to its plastic deformation during the bending operation, the plate supporting member 21 will also move responsively. This will prevent scratches, which would otherwise be formed due to a position shift between the outer surface of the metal plate W and the upper surfaces of the plate supporting members 21.
Although, as described above, the arrangement disclosed in Patent Document 4 is effective in order to prevent the scratches from being formed on the metal plate, the inventor's investigation has revealed that there still remains a problem to be solved.
This is undesirable formation of press-mark on the outer surface of the metal plate, which results from the slot 23 formed in the plate supporting member 21. More specifically, in accordance with the solution of Patent Document 4, the plate supporting member 21 is secured to the swingable member 15 by means of the fastener 25 passing through the slot 23 formed in the upper surface of the plate supporting member 21, to thereby allow the plate supporting members 21 to move along with the metal plate W, when the metallic plate W is elongated due to its plastic deformation during the bending operation. This will make it possible to prevent scratches from being formed due to relative displacement between the metal plate W and the plate supporting member 21. On the other hand, while the metal plate W is being pressed by the upper die 7, the outer surface of the metal plate W will become into contact under a greater pressure with the upper surface of the plate supporting member 21, which would damage the outer surface of the metal plate W to form thereon a press-mark having a contour corresponding to the slot 23.
Accordingly, a problem to be solved by the present invention is to provide a metal plate bending device with novel structure capable of efficiently bending a metal plate without scratching or denting the metallic plate. Another problem to be solved by the present invention is to prevent any damages from being formed on the metal plate, which would be caused by joints between the adjacent bending devices, when plural bending devices are connected in a lengthwise direction so as to bend a long-length metal plate.
To solve these problems, in one embodiment of the present invention, there is provided a metal plate bending device comprising a lower die having a main body with a pair of semi-circular cross-sectional recesses formed on an upper surface thereof in a symmetric design with respect to a center line and a pair of swingable members swingably received in said recesses respectively, and an upper die arranged above said lower die movably along the center line, wherein said upper die is moved toward a metal plate mounted on said lower die to impart a press-push force to the metal plate to thereby cause the swingable members to swing and at the same time bend the metal plate along the center line, characterized in that each of said swingable member has a movable plate unfixedly mounted on an upper surface of said swingable member, and spring means for providing a biasing force to move said movable plate in a mutually separating direction, said spring means still allowing said movable plate to move in a mutually approaching direction toward said swingable member against said biasing force along with expansion of the metal plate during the bending operation, said movable plates providing a completely flat metal plate supporting surface, and said spring means being positioned externally to provide no interfere with said flat metal plate supporting surface.
According to one embodiment of the present invention, in a metal plate bending device, it is characterized in that a spring means comprises coil spring or leaf spring.
According to one embodiment of the present invention, in a metal plate bending device, it is characterized in that movable plates are directly or indirectly secured by fasteners to swingable members in the outside of swingable members, heads of fasteners positioned externally of said movable plates acting as stopper means for maintaining said swingable members to stay in their starting position.
According to one embodiment of the present invention, in a metal plate bending device, it is characterized in that spring members comprising coil springs surrounding shafts of fasteners.
According to one embodiment of the present invention, in a metal plate bending device, it is characterized in that movable plates are mounted detachably.
According to one embodiment of the present invention, in a metal plate bending device, wherein a plurality of the metal plate bending devices are connected in series in a lengthwise direction for bending a metal plate longer than a length of a single metal plate bending device, it is characterized in that movable plates are long-length movable plates equal to or longer than the long-length metal plate, which are mounted successively over said plural metal plate bending devices.
In accordance with the present invention, the metal plate supported on the movable plates which, in turn, are slidably mounted on the swingable members of the lower die, is subjected to the bending operation, while swinging the swingable members, which will prevent formation of scratches on the metal plate. In addition, the movable plates provide a completely flat metal plate supporting surface with no hole and opening, which will prevent formation of press-mark on the metal plate. Accordingly, the metal plate may be bent with a completely undamaged surface, which will not lower its commercial value.
Further, the movable plates are biased by the spring members in such a manner that, when the metal plate expands due to its plastic deformation during the bending operation, the movable plates will move, against the biasing force, relative to the swingable members along with expansion of the metal plate, whereas, once the metal plate is removed from the lower die after the bending operation, the movable plates (and the swingable members) will soon be returned to their starting positions to become ready for the next bending operation, thanks to restoration of the spring members. The stopper means will work to more precisely return the movable plates to the starting positions and keep them thereat.
In accordance with an embodiment wherein the movable plates are mounted detachably, in a case wherein a plurality of the metal plate bending devices are connected in series in a lengthwise direction for bending a metal plate longer than a length of a single metal plate bending device, long-length movable plates may be used and mounted successively over the plural metal plate bending devices. This will prevent formation of any damages on the metal plate, which could otherwise be formed by joints between the adjacent bending devices. This will also be advantageous in respect of cost, because it is possible to replace the movable plate 35 only, when the movable plate should have been damaged by, for example, abrasion by relative movement to the metal plate W after repeated use for bending operation.
The metal plate bending device according to the present invention may be provided as a retrofit unit having some necessary parts to be fitted to an existing device or as a new complete device having all necessary parts.
The present invention will be described in detail in reference to some embodiments thereof.
This device 10 comprises an upper die 20 and a lower die 30 including a main body 31 and a pair of swingable members 32, 32. The upper die 20 is positioned above the lower die 30 and is movable (elevatable) along a center axis X of the main body 31. In its standby condition (
The upper surface of the lower die main body 31 has a pair of recesses 33, 33 in a symmetric manner with respect to the center line X. Each recess 33 has substantially a semi-circular cross-section with respect to its center axis, so that, when the swingable member 32 having substantially a semi-circular cross-section that corresponds to the inner wall shape of the recess 33 is received within the recess, the swingable member 32 is allowed to swing in both directions about its axis of rotation 34. The swingable members 32, 32 are normally biased by springs, not shown, toward the standby condition (
A movable plate 35 is mounted unfixedly on each of the swingable member 32. In the standby condition (
The lower portion of each swingable member 32 having substantially a semi-circular cross-section is partly cut out to form a step 37, and the swingable member 32 is secured, by a fastener such as a bolt 39, to a stationary plate 38 placed in contact with the step 37. The stationary plate 38 extends to the outside of the main body 31 and then is folded downwardly to a hang-down piece 40. In the standby condition (
As such, each swingable member 32 is secured to the stationary plate 38 by the bolt 39 in a manner that it is interposed from above and below between the movable plate 35 and the stationary plate 38. On the contrary, the movable plate 35 is not fixed to the swingable member 32 but simply placed thereon, so that the movable plate 35 is slidable with respect to the swingable member 32 along the contact surface therebetween.
The hang-down piece 36 of the movable plate 35 and the hang-down piece 40 of the stationary plate 38 extend substantially in parallel with each other with a space therebetween, in a region outside of the lower die main body 31, and their lower end portions are connected to each other by a fastener such as a bolt 41. A head 42 of the fastener 41 is positioned externally of the hang-down piece 36, and its shaft 43 extends through a hole (not shown) formed in the hang-down piece 36 to be fixedly connected to an attachment 44 that is secured by welding, for example, to the outside of the hang-down piece 40. A coil spring 45 surrounding the shaft 42 of the fastener 41 provides a biasing force for usually pushing the movable plate 35 apart from the stationary plate 38, and the head 42 of the fastener 41 will act as a stopper so as to maintain a predetermined distance therebetween. When the metal plate W expands due to its plastic deformation during the bending operation to be described later, the movable plate 35 will be moved along with expansion of the metal plate W in a direction approaching to the stationary plate 38, against the biasing force by the coil spring 45.
The movement and operation of this device 10 to be used to bend a metal plate W will now be described. At first, a metal plate W to be bent is placed on a pair of movable plates 35, 35 which provide a coplanar, horizontal metal plate supporting surface 44 in the standby condition (
From this condition, the upper die 20 waiting at the starting position remote above from the lower die 30 is driven to move downwardly, so that its leading end becomes into contact with the bending line of the metal plate W that is just aligned with the center axis X. Further descent will cause the swingable members 32, 32 to rotate in opposite directions about the axes of rotation 34, 34, so that the assemblies 46, 46 each having the movable plate 35, the stationary plate 38, the fastener 41 and the coil spring 45, etc. will also swing in the same directions together with the swingable members 32, 32.
As having been described in conjunction with the prior art, when the metal plate W is subjected to the bending operation, it will expand due to its plastic deformation. However, in accordance with the device 10 wherein the movable plates 35, 35 are arranged movably in the directions approaching to the stationary plates 39 against the biasing forces by the coil springs 45. Accordingly, when the metal plate W expands, the movable plates 35, 35 will responsively be moved in mutually approaching directions. The leading ends of the movable plates 35, 35 are positioned substantially in alignment with each other at the inner edges of the upper surfaces of the swingable members 32, 32 in the standby condition (
Consequently, in accordance with the device 10, when the metal plate W expands due to the plastic deformation during the bending operation, the movable plates 35, 35 supporting the metal plate will also move along with expansion of the metal plate W, so that there is no relative movement therebetween and no scratches should be formed on the metal plate W.
Moreover, the upper surfaces of the movable plates 35, 35 that provide the metal plate supporting surface 44 are absolutely flat and perfect with no hole and opening. Accordingly, even when subjected to the pushing force imparted by the upper die 20, no press-mark should be formed on the metal plate W (unlike with the device of Patent Document 4, as described before).
After the bending operation has been carried out in such manner, the upper die 20 is elevated and returned to the starting position (
The fastener 41 will connect the movable plate 35 to the stationary plate 38 and its head 42 will provide the stopper function, whereas the coil spring 45 will force the movable plate 35 toward the starting position and also allow the same to be moved relative to the swingable member 32 and the stationary plate 38 during the bending operation. As such, they have different functions and therefore may be arranged at different positions. However, as in the device 10, when the coil spring 45 is arranged to surround the shaft 43 of the fastener 41, the coil spring 45 can work stably, so this is a preferred embodiment.
The lower die 30 of the device 10 may be fabricated by adding the assemblies 46 to the existing lower die 30 including the main body 31 and the swingable members 32, 32. Accordingly, this embodiment may also be preferably used as a retrofit-type unit.
The device 10A is different from the device 10 according to Embodiment 1 in structure of a retrofitable unit or assembly. More specifically, each assembly 48 of the device 10A has a stationary plate 38 fixed by a fastener 39 to a swingable member 32 in contact with a lower step 37 of the swingable member 32, which is similar to the stationary plate 38 in the assembly 46 of the device 10 of Embodiment 1. However, with regard to a movable plate 35 slidably mounted on the upper surface of the swingable member 32, it extends outwardly in a small distance from a lower die main body 31 and the swingable member 32 and then is folded downwardly at an acute angle, and its leading end is connected to a hang-down piece 40 of the stationary plate 38, so that a part of a downward flap 49 will act as a leaf spring. In more detail, a folded plate 58 is superposed on the outside of the hang-down piece 40 of the stationary plate 38, and the leading end of the downward flap 49 of the movable plate 35 is inserted into a gap between a round bar 59, arranged inside of a folded portion of the folded plate, and the hang-down piece 40.
The downward flap 49 corresponds to the coil spring 45 in the device 10 of Embodiment 1 and will act substantially in the same manner. More specifically, when using the device 10A for bending the metal plate W, the metal plate W to be bent is placed on a horizontal metal plate supporting surface 44 that is defined by a pair of movable plates 35, 35 oriented coplanar in the standby condition (
During such operation, the assemblies 48, 48 also swing together with the swingable members 32, 32, and the assemblies 48, 48 having the downward flap 49,
49 will act by themselves as leaf springs. Therefore, when the metal plate W expands during the bending operation, the movable plates 35, 35 will be moved responsively in mutually approaching directions. The leading ends of the movable plates 35, 35 are positioned substantially in alignment with each other at the inner edges of the upper surfaces of the swingable members 32, 32 in the standby condition (
Accordingly, when the device 10A is used to bend the metal plate W, as in the preceding embodiment, there is no relative movement between the movable plates 35, 35 and the metal plate W supported thereon, so that no scratches should be formed on the metal plate W.
Moreover, the upper surfaces of the movable plates 35, 35 that form the metal plate supporting surface 44 are absolutely flat and perfect with no hole and opening. Accordingly, even when subjected to the press-push force imparted by the upper die 20, no press-mark should be formed on the metal plate W.
After the bending operation has been carried out in these manners, the upper die 20 is elevated and returned to the starting position (
The lower die 30 of the device 10 may be fabricated by adding the assemblies 48 to the existing lower die 30 including the main body 31 and the swingable members 32, 32. Accordingly, this embodiment may also be preferably used as a retrofit-type unit.
A detailed explanation will be given in reference to
A detailed explanation will be given in reference to
The lower die 30 of the device 10C may be fabricated by adding the leaf springs 52 formed integrally with the movable plates 35, 35 to the existing lower die 30 including the main body 31 and the swingable members 32, 32. Accordingly, this embodiment may also be preferable as a retrofit-type unit.
The metal plate bending devices 10, 10A, 10B, 10C according to the above-described embodiments are all designed such that the movable plate 35, capable of sliding along the upper surface of the swingable member 32 along with expansion of the metal plate W during its bending operation, is included as an element of the spring means (the coil spring 45, the downward flap 49, the coil spring 54, the round portion 55) itself. However, the movable plate 35 may be another member different and separate from the spring means, which is detachably connected to the spring means. Such embodiments are shown in
A detailed explanation will be given in reference to
Use of the metal plate bending device 10D according to Embodiment 5 will provide an additional advantage. More specifically, when the device is so designed that the shaft 43 of the fastener 41 extends through the lower end portion of the hang-down piece 36 of the movable plate 35 as in Embodiment 1, it is absolutely necessary that the movable plate 35 is shorter than the device. The metal plate W to be subjected to the bending operation has various length. If the device should be too long, it would be difficult to secure uniform accuracy over the entire length, and it would also be impractical in view of costs. Accordingly, in a practical prior art solution for bending a metal plate W having a length exceeding the length of one device, plural devices each having a predetermined length (200-300 mm, for example) are connected to each other in a lengthwise direction, and the metal plate W is mounted over the plural devices. However, when the long-length metal plate W is bent in such a manner, there exists a laterally extending joint or seam between the movable plates 35 of one device and the movable plates 35 of an adjacent device, which could sometimes result in a damage or mark to be formed on the metal plate W. Such laterally extending damage or mark should appear on the metal plate W at an interval of 200 mm, when the device has 200 mm length, thereby greatly degrading the product value.
In contrast, in the metal plate bending device 10D of Embodiment 5, the movable plate 35 is prepared as a separate, detachable member with respect to the spring means and, therefore, may be longer than the total device length L, which will solve the above-described disadvantage by using the movable plate 35 having its length corresponding to the length of the metal plate W to be bent. More specifically, as shown in
In addition, the metal plate bending device 10D of Embodiment 5 having the datable movable plate 35 is advantageous in respect to cost, because it is possible to replace the movable plate 35 only, when the movable plate should have been damaged by abrasion relative to the metal plate W after repeated use for bending operation. Moreover, the fact that the movable plate 35 is prepared as an independent member from the spring means (the coil spring 45) will make it easier to design the spring member having an appropriate spring force.
The metal plate bending device 10E according to Embodiment 6 shown in
The metal plate bending device 10F according to Embodiment 7 shown in
The metal plate bending device 10G according to Embodiment 8 shown in
Patent | Priority | Assignee | Title |
Patent | Priority | Assignee | Title |
6672127, | Jun 23 2000 | Yuugenkaisha Taigaa Koosan | Metal sheet bending device with rotation inhibiting function |
JP8057541, |
Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Mar 03 2015 | TOKYO SEIMITSU HATSUJO CO., LTD. | (assignment on the face of the patent) | / | |||
Oct 29 2015 | MAEDA, TAKAAKI | TOKYO SEIMITSU HATSUJO CO , LTD | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 037120 | /0400 |
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